al-rafidain engineering journal - cpas ramzy sediq al-omari... · prof. dr. basil m. saied laith a....
TRANSCRIPT
Volume 22 No.4 May 2014
Al-Rafidain Engineering
Journal
Iraqi National Journal for Engineering Science (Referred)
Published by College of Engineering- University of Mosul
ISSN 1813-0526 ) Print ) eISSN 2220-1729 ( Online )
For Enquiries: Editor-in-Chief Al-Rafidain Engineering Journal College Of Engineering University Of Mosul Mosul-Iraq
Website: http://www.uom-arej.org
E - mail: [email protected] Tel. 9647481870230
1. The views expressed in the issue are those of the authors and do not reflect
the views of the Editorial Board.
2. All texts are checked for plagiarism using "Grammarly" program.
3. The texts of the Journal are included in the International Index "EBSCO"
Editor-in-Chief:-
Prof. Dr. Abdul Hakim Hamed Ahmad
Secretary
Dr.Abbas Saiid Husain
Advisory Board
Editorial Board
Members
Prof. Dr. A. A. Almaini (Edinburgh Napier Univ.) Prof. Dr. S. M. Jamel (Mosul Univ.)
Prof. Dr. A. Abdul Sahib (Baghdad Univ.) Prof. Dr. M. T. Al-Layla (Mosul Univ.) Prof. Dr. A. Y. Na’ma n (Al Nahrin Univ.) Prof. Dr. A. Hachum (Mosul Univ.)
Prof. Dr. H. M. Fahmi (Al Nahrin Univ.) Prof. Dr. Kh. H. Sayidmarie (Mosul Univ.)
Prof. Dr. Kh. A. Joodi (Baghdad Univ.) Prof. Dr. B. M. Saied (Mosul Univ.)
Prof. Dr. M. A. Al-Jabry (Baghdad Univ.) Prof. Dr. R. R. Al-Omari (Al Nahrin Univ.)
Prof. Dr. M.Z. Mhammad ( Jordan Univ.) Prof. Dr. S. N. Hamad (Baghdad Univ.)
Prof. Dr. R. H. Al Suhaili (Baghdad Univ.) Prof. Dr. Hafsa R. Al-Omari (Mosul Univ.)
Prof. Dr. S. Y. Amen ( Univ. of Techna.) AsAssi. Prof. Dr. F. H. Ali (Mosul Univ.)
Prof. Dr. S. Y. Amen ( Univ. of Techna.)
Prof. Dr. TH. KH. Mahmood (Baghdad Univ.)
Al-Rafidain Engineering Vol. 22 No. 4 May 2014
ENGLISH SECTION
CONTENTS
No. Title Page No.
1. Settlement Analysis of a Piled Raft
Raid R. Al-Omari Ahmed F. Hassan
1
2. Softened Truss Model Theory for the Analysis of Fibre
Reinforced Concrete Deep Beams and Corbels
S. A. Al-Ta’an,
N. S. H. Al-Husaini,
12
3. Manufacturing of Bricks from Soil and Crushed
Limestone by Compression
M. O. Amin M. A. M. Khidir A. M. Taher
24
4. Systolic Video Stream Object Detector Using FPGA
Dr. Shefa A. Dawwd Ula T. Salim 33
5. An Adaptive Triple-Path Mechanism for Congestion Control in
Computer Networks
Jassim M. Abdul-Jabbar Omar A. Hazim
44
6. Digital Fractional Order PID Controller Design And
Realization
Abdelelah Kidher Mahmood Bassam Fadel Mohammed
57
7. Rapid Design and Test of Embedded Control Systems Using
LABVIEW-FPGA Tool
Dr. Maher Algreer Mohammad Tarik Mohammad
65
8. Permanent Magnet Synchronous Motor Drive Based
on Modified Space Vector Pulse Width Modulation
Prof. Dr. Basil M. Saied Laith A. Mohammed
74
9. Hybrid Fuzzy Logic Based A Particle Swarm Optimization
Controller Design for ZETA Converter
Dr. A. H. Ahmad N. S. Sultan
88
10. Neural Network Based on Model Reference Using for Robot
Arm Identification and Control
Rafid A. Khalil Rakan Kh. Antar
100
Civil
Engineering
Al-Omari: Settlement Analysis of a Piled Raft
1
Settlement Analysis of a Piled Raft Raid R. Al-Omari Ahmed F. Hassan
Professor, Civil Engineering Dept., Formerly Postgraduate Student
Alnahrain University, Baghdad, Iraq.
Abstract
Recently the concept of settlement piles has been introduced in which the spacing could be large when the purpose of using piles is to mitigate the settlement rather than resisting the load. For large spacing the effect of cap soil contact on the bearing capacity may increase therefore the new system is usually referred to as piled raft. It is yet not clearly indicated what number of piles or spacing is enough to maintain tolerable settlements. This ambiguity is the main problem of the present research besides some other relations. The software ANSYS version 11 has been used to model and analyze the piled raft. The raft and piles are represented using the 8-node isoparametric brick element SOLID 65 while the surrounding soil is represented using the 8-node brick element SOLID 45. The raft dimensions are kept constants, as well as the cohesion and the angle of friction of the soil. The Drucker-Prager soil yield model has been employed. The results indicate that there is a limiting number of piles represented by the total piles area relative to the group area which in general amounts to 3 to 4% after which there will be no significant advantage of increasing the number of piles to reduce settlement. This relative piles area is slightly affected by the stress level relative to the bearing capacity so that the factor of safety. Accordingly the pile spacing may significantly be increased if the settlement is the major concern. The ultimate bearing capacity was found to moderately increase with increasing the relative pile area up to the narrowest spacing used of 3D which is in agreement with the conventional knowledge. For the conditions investigated the effect of raft-soil contact was found to be not very significant.
تحليل الهبوط السس الركائز الحصيرية العمري احمد حسانرائد
جامعة النهرين -كلية الهندسة –قسم الهندسة المدنية
الخالصة
عندما يكون الغرض من استخدام الركائز هو التخفيف من الكبيره بين الركائز المسافاتمفهوم مؤخرا ستحدث أ قد لالهطول بدال من مقاومة الحمل. بالنسبه للمسافات الكبيره فان تأثير اتصال العوامه بالتربه على سعة التحمل قد تزيد من
هذه السعه و لذلك فان هذا النظام الجديد يشار اليه عادة بعوامة الركائز. ليس من الواضح لحد اآلن ما هو عدد الركائز او المسافه بين الركائز التي تكون كافيه للحفاظ على هطول مقبول. هذا
ان البحث العملي هو مكلف للغايه, حيثالغموض هو الموضوع الرئيسي لهذا البحث الى جانب بعض العالقات االخرى. .لتمثيل و تحليل عوامة الركائز ANSYS 11 برتامجدديه. تم استخدام فان هذه المشكله قد تم حلها بالطريقه الع
كما تم تمثيل التربه المحيطه (SOLID 65)لقد تم تمثيل العوامه و الركائز بأستخدام العنصر الطابوقي ذي الثماني نقاط متر 5.4متر طول, 9.6. ابعاد العوامه بقيت ثابته و هي (SOLID 45)بأستخدام العنصر الطابوقي ذي الثماني نقاط
ستخدم نموذج أ متر سمك, فضال عن التماسك وزاوية االحتكاك للتربه التي ايضا بقيت ثابته. و قد 5.4عرض و (Drucker-Prager) مثل بنسبة مجموع ي وعدد الركائز لحد وجود شارت النتائج الى أ لقدلتربه. لتمثيل سلوك ا
استفاده عموما لن تكون هناك % 5و 3الذي يتراوح عموما بين الحد ة الركائز الى مساحة المجموعه, و بعد ذلكمساحنسبة مستوى االجهاد الى سعة التحمل تأثر بمساحة الركائز تلنسبة هذة المن زيادة عدد الركائز لتقليل الهطول. ان مهمةبزيادة نسبة مساحة الركائز الى داد بشكل معتدلسعة التحمل القصوى تز جد ان عامل االمان. في نهاية المطاف فقد و أيكما قل مسافه مستخدمه بين الركائز و هي ثالثة امثال قطر الركيزه وهو ما يتفق مع المعارف التقليديه.استعمال أحد جدا وهو ايضا ما يتفق مع المعارف التقليديه. ؤثراجد ان تأثير االتصال بين العوامه والتربه ال يكون م و
Received: 33 – 4 - 2013 Accepted: 9 – 35 - 2013
Al-Rafidain Engineering Vol.22 No. 4 May 2014
2
settlement
skin
res
ista
nce
beari
ng re
sist
ance
pile
re
sis
tan
ce
Fig.1 Schematic diagram of the rate of development of
skin and bearing resistance of piles
Introduction
Piled raft foundation provides an economical foundation option for circumstances where
the performance of the raft alone does not satisfy the design requirements. Under these
situations, the addition of a limited number of piles may improve the ultimate load capacity,
the settlement and differential settlement performance, and the required thickness of the raft
[1].
This type of foundation consists of a footing, usually a raft, and a relatively small number
of friction/adhesion piles, this is referred to as a piled raft foundation. In this composite
foundation, the load transfer mechanism is fairly complex because the load is transmitted to
the soil through both the piles and the raft.
Piled Raft Philosophy
When the shear strength of soil is not adequate to support a shallow footing then the
conventional approach is to adopt piled foundation where the piles only are considered to
resist the applied load. However if the soil strength is fairly adequate but the immediate or
consolidation settlement is deemed excessive then the concept of piled raft may be introduced
in order to achieve economical savings.
It is known that the friction/adhesion resistance develops very much earlier than the
bearing resistance as shown schematically in Fig. 1. Bowles [2] indicated that 5-10 mm
penetration may be enough to develop full skin resistance in piles where about 10-30% of pile
base diameter is needed to develop the full bearing resistance.
Accordingly if a raft is fortified by some piles then upon loading the friction/adhesion of
piles will resist the load until the development of certain settlement when the raft bearing will
start contributing to the resistance, and the reaction to applied load will be shared by both the
piles and the raft. The economical privilege of such a composite system is that the full
ultimate capacity of piles is allowed to develop (piles safety factor =1) and the settlement may
very much be reduced compared with the settlement of raft alone.
Further information on pile raft composite system may be reviewed in Poulos [1] and Reul
and Randolf [3].
Al-Omari: Settlement Analysis of a Piled Raft
3
Piles Settlement Estimation Methods
The settlement of piles and pile groups is conventionally estimated by replacing the pile
groups by a fictitious footing located at a certain depth below the surface mostly taken as two-
third of the piles length. The settlement of this footing corresponds to the settlement of the
pile group [4]. Alternatively the theory of elasticity may be employed through the Mindlin
solution for a point load at the interior of an elastic solid [5, 2].
During the last decades, the finite element method has been initiated and rapidly
developed. The method is applicable to many engineering fields including geotechnical
engineering. The load-settlement relation of piled raft may be obtained using an elasto-plastic
constitutive relation for the soil which yields more reliable results.
Finite Element Analysis of the Piled Raft
In this study a general finite element program "ANSYS 11.0" was selected to generate the
solution for the analysis of piles under vertical loads. In this version, new features and
enhancements are added, like the extension of the contact elements that provide robust
simulation of general non-linear contact between rigid and deformed surfaces using three-
dimensional elements.
In this work two types of elements are selected. The first one is Solid 65 to represent the
concrete (raft and piles).The second one is Solid 45 to represent the soil under the raft. Both
elements are three–dimensional brick elements.
Solid 45 element is defined by eight nodes having three degrees of freedom at each node:
translations in the nodal x, y and z directions as shown in Fig. 2. The element has plasticity,
creep, swelling, large deflection and large strain capabilities [6].
Fig. 2 Solid 45 three dimensional structural solid elements [6]
Solid 65 elements are used for the three–dimensional modeling of concrete solids without
reinforcing bars. The solid is capable of cracking in tension and crushing in compression. The
element is defined by eight nodes having three degrees of freedom at each node: translation in
the nodal x, y and z directions. The concrete element is similar to the solid 45 element with
the addition of special cracking and crushing capabilities [6].
Al-Rafidain Engineering Vol.22 No. 4 May 2014
4
The type of yield criterion used to characterize the behavior of the soil through this study
is the Drucker–Prager model. The Drucker–Prager failure surface can be looked upon as a
smooth Mohr–Coulomb surface or as an extension of Von-Mises surface for hydrostatic
pressure–dependent materials such as soil.
In the combined-iterative procedure, a combination of the incremental and iterative
scheme is used. For the incremental-iterative solution, Full Newton-Raphson procedure has
been used in this study. The stiffness matrix is formed at every iteration. The advantage of
this procedure is to give more accurate results, the disadvantage is that a large amount of
computational effort may be required to form and decompose the stiffness matrix.
Table 1: Models of the numerically tested piled raft
In the present problem, the foundation consists of three parts: raft, piles and soil. The main
goal of the present research is to explore the effect of piles and pile configuration on the
settlement of raft, also to ascertain the effect of ignoring the raft-soil contact on the raft
bearing capacity. Therefore, the program is set up to numerically analyze different models of
a piled raft to fulfill the research goal. The size of the raft has been maintained constant at
4.5x6.9x0.50 m, as typically shown in Fig. 3, in order for the size effect not to interfere with
effect of piles on the settlement. The pile length was not altered and kept at 15 m. The main
parameters were the number and diameter of the piles. Table 1 presents the research program.
The material properties of the piled raft foundation are shown in Table 2. All models have
the same material properties.
Table 2 Material properties of the models
No. of
nodes
No. of
elements
Spacing
between
piles, s (m)
Raft-soil
contact
condition
pile
dia., D
(m)
No. of
piles
Model
no.
41044 170200 3D Contact 0.4 4x6 1
51072 167812 3D No contact 0.4 4x6 2
41276 172348 3.75D Contact 0.4 3x5 3
53052 178856 3.75D No contact 0.4 3x5 4
17188 69056 5D Contact 0.4 2x4 5
18984 61940 5D No contact 0.4 2x4 6
15108 57584 7.5D Contact 0.4 2x3 7
16764 52484 7.5D No contact 0.4 2x3 8
2764 11546 ------ Contact ------- 0x0 9
16092 62652 3.2D Contact 0.6 2x4 10
17160 56316 3.2D No contact 0.6 2x4 11
14916 56632 4.8D Contact 0.6 2x3 12
16172 52688 4.8D No contact 0.6 2x3 13
14252 52832 3.5D Contact 0.8 2x3 14
15353 48744 3.5D No contact 0.8 2x3 15
properties
material
Modulus of
elasticity,
E (MPa)
poisson’s
ratio, cohesion, c
(kN/m2)
angle of
internal
friction, ϕ0
concrete 25000 0.15 ------- -------
clay 25 0.35 35 0
Al-Omari: Settlement Analysis of a Piled Raft
5
In reference to the boundary conditions, all the models are fixed from all the sides, and the
pressure is uniformly distributed on the top area of the raft. More details may be consulted in
Hassan [7].
Fig. 3 A configuration of {4x6} piles (pile diameter=0.4m).
Determination of Ultimate Bearing Capacity
The ultimate capacity can, crudely, be defined as the load under which a rapid movement
occurs under sustained or slight increase in the applied load. On most occasions, a distinct
plunging ultimate load is not obtained in the field or numerical test as typically illustrated in
the presently obtained pressure-settlement relations of Fig. 4. Therefore, the pile capacity or
ultimate load must be determined by some methods based on the load-settlement data.
Fellenius [8, 9] presented nine different methods of pile capacity evaluation from load
settlement records of a static loading test, the most important of which is the DeBeer Yield
Limit method also known as the log-log method. Budhu [10] presented the Tangets method.
Fig. 4 Load-settlement curves for model 1{4x6} piles (pile diameter=0.4m) [raft
area=6.9x4.5m]
0
500
1000
1500
2000
2500
0 50 100 150 200 250 300 350
settlement(mm)
pre
ss
ure
(kN
/m2
)
4x6 piles rsc d =0.4m
4x6 piles no rsc d =0.4m
Al-Rafidain Engineering Vol.22 No. 4 May 2014
6
If a trend is difficult to discern when analyzing data, a well known trick is to plot the data
to logarithmic scale rather than to linear scale and made use of the logarithmic linearity by
plotting the load-settlement data in a double-logarithmic diagram. If the ultimate load was
reached in the test, two line approximations will appear; one before and one after the ultimate
load (provided the number of points allows the linear trend to develop). The slopes are
meaningless, but the intersection of the lines is useful as it indicates where a change occurs in
the response of the piles to the applied load. DeBeer called the intersection as the Yield Load.
An example from the present work is given in Fig. 5.
When the pressure-settlement relation yields two almost linear portions as typically shown
in Fig. 6, then in the tangent method the intersection of the tangents to those two portions
represent the failure point.
Fig. 5 Ultimate bearing capacity by log-log method for 4x6 piles with raft-soil contact (pile
diameter=0.4m).
Fig. 6 Ultimate bearing capacity obtained by tangents method for 0x0 piles.
Al-Omari: Settlement Analysis of a Piled Raft
7
Table 3 Ultimate bearing capacities and settlements of the numerically tested piled raft
To determine the ultimate bearing capacity from the numerical models solved in the
present work, the two aforementioned methods are employed. Table 3 presents the ultimate
bearing capacities and settlements for each model.
In order to verify the bearing capacity results presently obtained from ANSYS, the
results would be compared with Terzaghi Method commonly known as the Solid Block
Method.
Assuming the pile cap is perfectly rigid and the soil contained within the periphery
circumscribing all the piles behaves as a solid block, the entire block may be visualized as one
deep footing. Naturally this assumption is valid for closely spaced piles therefore; the
computer results would be compared with Terzaghi results for the case of 6x4 piles.
The parameters used are c=35kN/m2, depth=15m, B=least dimension=4.5m. The
calculated bearing at the tip is 297.5 kN/m2
whereas the block shear resistance per area of
group is 426.5 kN/m2. Thus, the total bearing capacity becomes 724 kN/m
2.
Using the Tangents method, the numerical ultimate bearing capacity for (4x6) piles is
675kN/m2 which is very close to that calculated using Terzaghi method. In finite element
analysis the agreement of 93% with the limiting equilibrium method is usually considered to
be very optimistic.
Settlement Results
The work is aimed at quantifying the advantage of using piled raft to reduce settlement
and also to quantify the effect of pile spacing and pile diameter on settlement, also to assess
the effect of raft-soil contact and the effect of the ratio of total piles area to group area.
According to the literature survey conducted, previous numerical research exhibited the
load-settlement relations without performing the parametric studies required for taking
Model
(No. of
piles)
Dia.
(mm)
Spacing qult
(kN/m2)
(log-log
method)
qult
(kN/m2)
(tangent
method)
average
qult
(kN/m2)
Settlement at
working load
(mm)
[Tangent
Method]
Settlement at
ultimate load
(mm)
[Tangent
Method]
4x6 rsc 0.4 3d 560 675 618 5.25 22
4x6 no rsc 0.4 3d 550 650 600 5.75 22.5
3x5 rsc 0.4 3.75d 530 630 580 4.75 22.5
3x5 no rsc 0.4 3.75d 530 630 580 4.75 23.5
2x4 rsc 0.4 5d 515 593 554 6 26
2x4 no rsc 0.4 5d 505 585 545 6.25 28
2x3 rsc 0.4 7.5d 520 625 573 6.75 38
2x3 no rsc 0.4 7.5d 500 610 555 7.5 45
2x4 rsc 0.6 3.2d 580 630 605 5.75 23
2x4 no rsc 0.6 3.2d 550 608 579 6 25
2x3 rsc 0.6 4.8d 530 605 568 6.25 28
2x3 no rsc 0.6 4.8d 520 583 552 6.5 28.5
2x3 rsc 0.8 3.5d 585 642 614 5.5 29.2
2x3 no rsc 0.8 3.5d 555 620 588 6.3 30.5
0x0 ---- ------ ------ 450 450 12.5 81
Al-Rafidain Engineering Vol.22 No. 4 May 2014
8
decisions in the design. Experimental investigations on this subject are of the utmost
importance but they are expensive and require a good laboratory.
The load-settlement relationships are obtained for piled rafts with two cases: raft-soil
contact, denoted by "rsc", and no raft-soil contact, denoted by "no rsc". Typical load-
settlement relationships are shown in Figs. 4 and 6. All the load-settlement curves may be
consulted in Hassan [7] where it appeared that the results are compatible and rational.
The working load is obtained by dividing the ultimate bearing capacity by (3) for all
models. Then the results are marked on the load-settlement curves for each model to
determine the settlement at working load. The settlement at ultimate load is also obtained by
marking the ultimate bearing capacities on the load-settlement curves and determining the
settlements. The obtained values are shown in Tables 3 using the Tangents method.
The effect of number of piles including implicitly the spacing between them and the
raft-soil contact on the settlement at working and ultimate loads would be considered.
It appears that the settlement of the raft, in contact with soil, at ultimate load sharply
drops with increasing the number of piles (n) from zero to 6 and this drop continues until n=8.
Further increase in n would moderately increase the ultimate bearing capacity, Table 3, but
would not significantly influence the settlement as demonstrated in Fig. 7. At working load,
the settlement is reduced at n=6 and then the effect of increasing n almost vanishes.
If the raft is not in contact with soil then increasing n from 6 to 8 causes a sharp drop in
settlement at the ultimate load after which the effect of increasing n diminishes as shown in
Fig. 8. The effect of contact condition on settlement increases with decreasing n. The lack of
contact decreases the bearing capacity but not to a considerable extent.
Table 3 indicate that the lack of contact increases the settlement both at working and
ultimate loads by an average of 4.97% and 7.2% respectively using the Tangents method. The results using larger pile diameter of 0.6m, although limited but give indications to
the same conclusions, Table 3.
Fig. 7 Settlement at working and ultimate loads vs. number of piles using the Tangents
method(rsc and pile diameter = 0.4m).
pile diameter=0.4m
0
10
20
30
40
50
60
70
80
90
0 10 20 30
number of piles
se
ttle
me
nt(
mm
)
settlement at working load
for rsc
settlement at ultimate load
for rsc
Al-Omari: Settlement Analysis of a Piled Raft
9
Fig. 8 Settlement at working and ultimate load vs. number of piles using the Tangents method
(no rsc and pile diameter = 0.4 m).
These findings are interpreted on the bases that the skin resistance mobilizes very much
earlier than the bearing or base resistance, Fig. 1, therefore a small number of piles can
significantly reduces the settlement and that is why the skin resistance may reach its ultimate
value while the bearing is at the beginning of progress. Therefore the skin resistance, when
sufficient, may not give the chance to the full mobilization of raft bearing.
Foundation designers may sometimes suggest a large number of piles beneath structures
subjected to low load like clarifiers. They argue that although the bearing capacity is
adequate, the piles are needed to prevent excessive settlement. Great economical losses have
been imposed due to such arguments. It is thought that small number of piles (large spacing)
can sufficiently reduce the settlement which in turn greatly reduces the foundation cost.
In order to normalize the results so that the designers can make use of them irrespective
of the area and shape of the cap, the settlement will presently be related to the ratio of total
piles area to the area of the group. Figures 9 and 10 demonstrate the variation in settlement
according to this ratio when the pile diameter is 0.4m. It is clear that increasing the piles area
sharply reduces the settlement. Indeed a small pile area of generally 3 to 4% is enough after
which there will be no further significant reduction in settlement. This small area slightly
depends on the stress level relative to the bearing capacity of the piled raft, in other word
every value for this limiting area corresponds to certain values of spacing and factor of safety.
Figures 9 and 10 highlight the goal of the present work and indicate these values which would
hopefully be useful for the foundation designers until more data can be obtained to revise the
present data. However, not enough data are available when the pile diameter is larger than
0.4m, nevertheless the results given in Table 3 may lead to the same conclusions.
Although Figs. 9 and 10 are accomplished using certain soil properties and certain piled
raft configurations and geometry, the results should be indicative for other cases.
pile diameter=0.4m
0
5
10
15
20
25
30
35
40
45
50
0 10 20 30
number of piles
se
ttle
me
nt(
mm
)
settlement at working
load for no rsc
settlement at ultimate
load of no rsc
Al-Rafidain Engineering Vol.22 No. 4 May 2014
11
Fig. 9 Settlement at constant load vs. (area of piles/area of group)% for rsc (pile
diameter = 0.4m)
Fig. 10 Settlement at constant load vs. (area of piles/area of group) % for no rsc
(pile diameter = 0.4m)
Conclusions
The three dimensional finite element software of ANSYS program has been used for the
analysis of piled raft system including many parameters like number of piles, diameter of piles,
and raft-soil contact condition. The following conclusions are drawn;
0
10
20
30
40
50
60
70
80
90
100
110
0 2 4 6 8 10 12 14
(area of piles/area of group)%
settlem
en
t(m
m)
settlement at 200kN/m2
settlement at 300kN/m2
settlement at 400kN/m2
settlement at 500kN/m2
0
5
10
15
20
25
30
0 5 10 15
(area of piles/area of group)%
se
ttle
me
nt(
mm
)
settlement at 200kN/m2
settlement at 300kN/m2
settlement at 400kN/m2
settlement at 500kN/m2
Al-Omari: Settlement Analysis of a Piled Raft
11
1- The number of piles, or the spacing, under the same raft has been set up in the form of the
ratio of total piles area to group area and diagrammatically presented against the
settlement. It has been noticed that there is a limiting small value of this relative piles area
which amounts to 3 to 4% after which the settlement, in general, does not significantly
decreases with increasing the number of piles. This limiting ratio is influenced by the
adopted factor of safety. This is thought to be an important finding to significantly reduce
the foundation cost of many structures.
2- As far as the present research is concerned it has been revealed that the log-log method and
the Tangents method are the most suitable methods to estimate the ultimate bearing
capacity from the load-settlement relations of the piled raft foundation.
3- Increasing the relative piles area over the limiting value for settlement moderately
increases the ultimate bearing capacity.
4- With reference to the effect of pile diameter, it has been noticed that whenever the
diameter increases the settlement at ultimate load decreases.
5- The advantage of raft-soil contact in increasing bearing capacity is noticeable but not
significant, it presently reached up to 4% whereas the same effect on settlement at ultimate
load is more pronounced and it reached up to 15%.
Acknowledgment
The work is conducted in the Civil Engineering Department/ Alnahrain University and
represents the M.Sc. thesis of the second author under the supervision of the first author.
References
1. Poulos, H.G. “Piled Raft Foundations: Design and Applications”, Geotechnique, Vol.
51, No. 2, 2001, pp. 95-113.
2. Bowles, J. E., “Foundation Analysis and Design”, McGraw-Hill Int. Book Company,
1996.
3. Reul, O., and Randolph, M. F, “Piled Rafts in Over Consolidated Clay: Comparison of
in Situ Measurements and Numerical Analysis”, Geotechnique, Vol. 53, No. 3, 2003.
4. Peck, R., Hanson, W. and Thornburn, T., “Foundation Engineering”, John Wiley &
Sons, USA, 1974.
5. Poulos, H.G. and Davis E. H., “The Settlement Behavior of Single Axially Loaded
Incompressible Piles and Piers”, Geotechnique, Vol. 18, No. 3, 1968, pp. 351-371.
6. ANSYS basic analysis procedure, ANSYS Program, USA, 2005.
7. Hassan, A. F., “Finite Element Analysis of a Piles Raft”, M.Sc. thesis, Alnahrain
University, Iraq, 2009.
8. Fellenius B.H., “Test Loading of Piles. Methods, Interpretation, and New Proof
Testing Procedure”, ASCE, Vol.101, Gt9, 1975, pp. 855-869.
9. Fellenius B.H., “The Analysis of Result From Routine Pile Loading Test”, Ground
Engineering, London, Vol.13, No.6, 1980, pp. 19-31.
10. Budhu M., “Soil Mechanics and Foundations”, John Wiley and Sons, 2nd
edition 2007.
The work was carried out at the college of Engineering. Alnahrain University, Baghdad, Iraq.